EP1391893A1

EP1391893A1 - Hard disc drive

Info

Publication number: EP1391893A1
Application number: EP03018568A
Authority: EP
Inventors: Sang-Chul Shin; Woo-Cheol Jeong; Chul-Woo Lee
Original assignee: Samsung Electronics Co Ltd
Current assignee: Samsung Electronics Co Ltd
Priority date: 2002-08-19
Filing date: 2003-08-18
Publication date: 2004-02-25
Anticipated expiration: 2023-08-18
Also published as: US7133248B2; US20040095679A1; KR20040016691A; JP3949090B2; DE60316880D1; KR100468760B1; JP2004079165A; DE60316880T2; EP1391893B1

Abstract

A hard disc drive is provided. The hard disc drive includes a base including a moving region in which an air damping ramp, adjacent to a recording surface of a disc, a slider, and a driving unit, which holds the slider, move. The bottom of the moving region is lower than the air damping ramp, and has a channel that is recessed at the bottom of the moving region and extends along the moving path of the slider. This structure reduces a vortex that forms around a head gimbal assembly (HGA) due to the application of insufficient preload onto HGA or a defective HGA. Accordingly, vibration of the HGA due to the vortex decreases, thus rendering a position error signal (PES) more accurate and reliable.

Description

The present invention relates to a hard disc drive in which vibration of a slider due to a flow of air caused when a disc rotates can be effectively reduced.
FIG. 1 is a cross-sectional view of a general single channel type hard disc drive that drives a single disc or a single head. Referring to FIG. 1, the hard disc drive includes a disc 1 having a recording surface on which information is recorded, and a head gimbal assembly (HGA) 2.
The disc 1 is rotated by a spindle motor 4 installed on a base 3. The HGA 2 includes a slider (not shown) having a magnetic head for writing data on and reading data from the recording surface of the disc 1. The HGA 2 is combined with a suspension 7 that is combined with an actuator 6 that is driven by a voice coil motor 5 to rotate with respect to a pivot bearing 6a. The structure of the HGA 2 is well known in the field of disc recording/reproducing apparatuses, and therefore its detailed description will be omitted here.
The recording surface of the disc 1 faces the base 3, and the HGA 2 is positioned between the base 3 and the disc 1 and moves along the recording surface of the disc 1. As shown in FIG. 2, a space for the disc 1 and the aforementioned related elements is encompassed by a frame 3a. The frame 3a is closely adhered with a lid (not shown) that seals the space. A ramp 3b is formed, very close to the recording surface of the disc 1, at the bottom of the base 3, so as to form an air damping region of the disc 1. A slider moving region 3c is a place where the HGA 2 and the suspension 7, which holds the HGA 2, move. The slider moving region 3c is lower than the ramp 3b. Also, a recession 4b is formed at a flange 4a of the spindle motor 4 to be level with the slider moving region 3c. The recession 4b allows the suspension 7 to move within the slider moving region 3c. In conclusion, the ramp 3b is lower than the flange 3a and the slider moving region 3c is lower than the ramp 3b. Also, the distance between the disc 1 and the base 3 is set to be very narrow, except at the slider moving region 3c.
In such a hard disc drive, the disc 1 rotates within a space defined by the base 3 and the lid which is put on the base 3 to close the space. The rotation of the disc 1 enables air to flow along the shape of the space formed in the hard disc drive. The rotation of the disc 1 results in a flow of air in the hard disc drive, and then, the flow of air causes the HGA 2 to rise to an equilibrium position where a rising force from the flow of air is equal and opposite to a preload (or gramload) applied to the head. A head suspension assembly (HSA), which consists of the HGA 2 and the suspension 7, vibrates due to the flow of air caused by the rotation of the disc 1. That is, the suspension 7 and the HGA 2, which is attached to the front of the suspension 7, vibrate due to the flow of air in the hard disc drive. The suspension 7 and the HGA 2 vibrate with a particular bandwidth of frequency, especially, around 10 KHz.
In general, the HSA is set to apply a preload to the slider so that the slider can has rising height (Z-height) in accordance with the rotation speed. However, if excessive or insufficient preload is applied to the slider or the slider is abnormally positioned in the HGA 2, the suspension 7 and the HGA 2 locally vibrate to a large degree at a particular frequency bandwidth, e.g., 10 KHz. This local vibration deteriorates a position error signal (PES), and as a result, causes errors. For instance, when the slider (more specifically, a reading element or a writing element included in the slider) performs reading/writing operations at a target track, the vibration could cause the slider to read data from or write data to an adjacent track, not the target track, thereby deteriorating the performance of the hard disc drive, as well as the servo characteristics of the hard disc drive.
The present invention provides a hard disc drive in which vibration of an HGA due to flow or air can be effectively suppressed.
According to an aspect of the present invention, there is provided a hard disc drive including a disc on which information is stored; a slider including a head that performs reading and writing operations on the disc; a driving unit that drives the slider; and a base including an air damping ramp adjacent to a recording surface of the disc, and a moving region in which the slider and the driving unit move, the bottom of the moving region being lower than the air damping ramp. Here, a channel is formed to be recessed at the bottom of the moving region, the channel extending along the moving path of the slider.
The channel may be a predetermined distance from an edge of the air damping ramp or extend to the air damping ramp.
It is preferable that the sidewalls of the channel are inclined with respect to the bottom of the channel, and the sidewalls of the channel are inclined to degrees of 45 or less.
It is preferable that the channel is formed beneath the slider.
The driving unit includes an actuator arm rotating under the power of a voice coil motor installed in the base, and a suspension, one end of which is combined with the actuator arm and the other end of which is combined with the slider.
The above and other aspects and advantages of the present invention will become more apparent by describing in detail preferred embodiments thereof with reference to the attached drawings in which:
FIG. 1 is a schematic plan view of a conventional hard disc drive;
FIG. 2 is a cross-sectional view of the hard disc drive of FIG. 1;
FIG. 3 is a schematic plan view of a hard disc drive according to one embodiment of the present invention;
FIG. 4 is a cross-sectional view of the hard disc drive of FIG. 3;
FIGS. 5A and 5B are magnified views of the hard disc drives shown in FIGS. 2 and 4, respectively;
FIG. 5C is a cross-sectional view of a hard disc drive according to another embodiment of the present invention; and
FIGS. 6 through 8 are graphs illustrating radial head frequency response of the hard disc drives shown in FIGS. 5A through 5C when a normal head gimbal assembly (HGA) and an abnormal HGA are applied to these hard disc drives, respectively.
FIG. 3 is a schematic plan view of a single-channel hard disc drive, which adopts a single disc and a single head, according to a first embodiment of the present invention. The hard disc drive of FIG. 3 includes a channel 30d in a slider moving region 30c to move a head gimbal assembly (HGA) 20 and a suspension 70 within the slider moving region 30c. The channel 30d extends a path along which air flows on an upper surface of a base 30.
Referring to FIG. 3, a disc 10, which includes a recording surface, i.e., the bottom, on which information is recorded, is combined with a spindle motor 40 installed on the base 30. The disc 10 is encircled by a frame 30a and an air damping ramp 30b is formed, adjacent to the recording surface (bottom) of the disc 10, at the interior of the frame 30a. Also, the HGA 20 is positioned at the recording surface of the disc 10 and further includes a slider (not shown) having a magnetic head that performs reading and writing operations. As is known in the related art, the slider includes reading and writing elements that read information from and write information to the recording surface of the disc 10. One end of the suspension 70 is combined with the HGA 2 and the other end thereof is combined with an actuator 60 that rotates about a pivot bearing 60a under the power of a voice coil motor 50.
As mentioned above, the HGA 2 and the suspension 70, which holds the HGA 20, are installed in the slider moving region 30c. The slider moving region 30c is formed through the air damping ramp 30b such that the air damping ramp 30b takes on a 'C" shape formed around a rotating axis of the disc 10.
Referring to FIGS. 4 and 5B, the recording surface of the disc 10 is very close to an upper surface of the air damping ramp 30b on the base 30. Around the outer perimeter of damping ramp 30b, the frame 30a acts as a flange. The frame 30a is adhered with a lid (not shown) that covers the disc 10 and the aforementioned related elements.
The slider moving region 30c, in which the HGA 20 and the suspension 70 move, is shaped to be deeper than the air damping ramp 30b. For the movement of the suspension 70, a flange 40a of the spindle motor 40 includes a recession 40b that is level with the slider moving region 30c. That is, the air damping ramp 30b is lower than the frame 30a and the slider moving region 30c is lower than the air damping ramp 30b. The distance between the disc 10 and the base 30 is set to be very narrow, except at the slider moving region 30c.
The channel 30d, which is defined by sidewalls a and b, is formed to a predetermined depth at the bottom of the base 30 directly under the HGA 20, thereby making the path of the flow of air longer. The bottom of the channel 30d is connected to the bottom of the slider moving region 30c via the sidewalls a and b, and the surface of the air damping ramp 30b is connected to the bottom of the slider moving region 30c via an incline plane c and a rounded edge of the air damping ramp 30b as shown in FIG. 5B. It is preferable that the sidewalls a and b have slopes of degrees of 45 or less in order to suppress the occurrence of vortex during the flow of air. Further, it is preferable that the incline plane c of the air damping ramp 30b has also a slope of degree of 45 or less.
As shown in FIG. 5B, a central line X-X' passing through the HGA 20 intersects the bottom of the channel 30d at predetermined distances L1 and L2 from the sidewalls a and b. The formation of the channel 30d largely suppresses vibration of the HGA 20 and the suspension 70, particularly, local vibration at a frequency of approximately 10 KHz due to the application of an abnormal preload to the slider or inappropriate assembling of the slider with the HGA 20.
A preload is applied to a head suspension assembly which includes the HGA 20 and the suspension 70 holding the HGA 20. Thus, when the disc 10 rotates in the hard disc drive, the slider rises to an equilibrium position where a balance between force on the slider due to the air flow and the preload is achieved. The preload is predetermined to obtain a desired equilibrium distance from the recording surface of the disc. When the slider rises to the equilibrium position, the flow of air results in the formation of a vortex at the front of the suspension 70, particularly, around the HGA 20, thereby causing abnormal vibration of the HGA 20. The HGA 20 vibrates more intensely when the preload applied to the HGA 20 is not precisely determined in consideration of the rotation speed of the disc 10.
To prevent vibration of the HGA 20, the hard disc drive according to the present invention further includes the channel 30d, which has the inclined sidewalls a and b, in the base 30. With the formation of the channel 30d, it is possible to widen the passage through which air flows past the HGA along the surface of the base 30 to make the air also flow along the inclined sidewalls a and b and the bottom of the channel 30d, adjacent to the HGA 20. As a result, the flow rate of air decreases to reduce the vortex formed around the HGA 20, and thus, vibration of the HGA 20 due to the vortex also decreases.
The base 30 according to a second embodiment of the present invention includes a channel 30d' as shown in FIG. 5C. As compared to the channel 30d according to the first embodiment, the length of the channel 30d' extends to an air damping ramp 30b and the channel 30d' has an inclined sidewall b' which is combined with the sidewall b and the incline plane c of the channel 30d of FIG. 5B. Referring to FIG. 5C, a central line X-X' passing through an HGA 20 intersects the bottom of the channel 30d' at predetermined distances L1 and L3 from the inclined sidewalls a and b'. Like in the base 30 according to the first embodiment, it is preferable that the sidewalls a and b' of the channel 30d' have slopes of degrees of 45 or less.
FIG. 6 is a graph illustrating radial head frequency response of a conventional hard disc drive. FIGS. 7 and 8 are graphs illustrating radial head frequency responses of hard disc drives according to preferred embodiments of the present invention.
B1 denotes the base 3 of the conventional hard disc drive of FIG. 1, the base 3 including a slider moving region having a flat surface as shown in FIG. 5A. B2 denotes the base 30, shown in FIG. 4, of a hard disc drive according to the first embodiment of the present invention, the base 30 having the channel 30d beneath the HGA 20 as shown in FIG. 5B. B3 denotes the base 30 in a hard disc drive according to the second embodiment of the present invention, shown in FIG. 5C. H1 denotes an HGA whose performance is good except that an insufficient preload is applied thereto, or an HGA with structural defects. H2 and H3 denote normal HGAs of different types whose performances are good, an appropriate preload is applied thereto, and they are structurally stable. For instance, B1H1 denotes a conventional hard disc drive including a base with a flat slider removing region, and an HGA to which an insufficient preload is applied or which has structural defects.
Referring to FIG. 6, if the defective HGA H1 is attached to the general base B1 having no channel, high-displacement vibration occurs in the hard disc drive at particular frequencies. Such vibration interrupts a position error signal (PES), in particular, at about 10 KHz, thereby deteriorating the performance of the hard disc drive.
Referring to FIG. 7, when the defective HGA H1 is installed in the base 30 B3 having the channel 30d' shown in FIG. 5C, vibration is markedly reduced, especially, around 10 KHz, compared to FIG. 6.
FIG. 8 illustrates the radial head frequency responses of hard disc drives having the normal HGAs H2 and H3 installed in the three types of bases B1, B2, and B3, respectively. FIG. 8 reveals that the hard disc drives show almost the same radial head frequency responses regardless of the presence of a channel in a base if the normal HGAs H2 and H3 are adopted.
Also, FIGS. 6 through 8 reveal that it is possible to significantly reduce vibration of an HGA when the bases B2 and B3 having the channels 30d and 30d' of FIGS. 5B and 5C are used.
As described above, in a hard disc drive according to the present invention, a channel is formed in a slider moving region, thus reducing a vortex occurring around a head gimbal assembly (HGA) due to the application of insufficient preload to the HGA or a defective HGA. Accordingly, vibration of the HGA caused by the vortex decreases, and a position error signal (PES) becomes more accurate and reliable.

Claims

A hard disc drive comprising:

a disc (10) on which information is stored;

a slider including a head that performs reading and writing operations on the disc;

a driving unit that drives the slider; and

a base (30) including an air damping ramp (30b) adjacent to a recording surface of the disc, and a moving region (30c)in which the slider and the driving unit move, the bottom of the moving region being lower than the air damping ramp (30b),

wherein a channel (30d) is formed to be recessed at the bottom of the moving region, the channel extending along the moving path of the slider.
The hard disc drive of claim 1, wherein the channel is a predetermined distance from an edge of the air damping ramp (30b).
The hard disc drive of claim 2, wherein the sidewalls (a,b) of the channel are inclined with respect to the bottom of the channel (30d).
The hard disc drive of claim 3, wherein the sidewalls (a,b) of the channel are inclined to degrees of 45 or less.
The hard disc drive of claim 2, wherein the end of the air damping ramp, which faces the moving region, is inclined.
The hard disc drive of claim 2, wherein the channel is formed beneath the slider.
The hard disc drive of claim 1, wherein the channel extends to the air damping ramp.
The hard disc drive of claim 7, wherein the sidewalls (a,b) of the channel are inclined with respect to the bottom of the channel.
The hard disc drive of claim 8, wherein the sidewalls of the channel are inclined at degrees of 45 or less.
The hard disc drive of claim 7, wherein the channel is formed beneath the slider.
The hard disc drive of claim 1, wherein the driving unit comprises:

an actuator arm (60) rotating under the power of a voice coil motor (50) installed in the base; and

a suspension (70), one end of which is combined with the actuator arm and the other end of which is combined with the slider.